Monitoring system for an industrial plant

ABSTRACT

A monitoring system for an industrial plant, in particular for a power station plant, has a number of plant parts which can be represented as information elements on a display unit. For the purposes of information compression, filtering and diagnosing faults in good time, the information elements can be displayed in a positioned manner by using process data that are relevant for a plant state in such a way that the distance between two information elements in each case represents the degree of their contextual similarity.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a Continuation of International Application Ser. No. PCT/DE95/01466, filed Oct. 23, 1995 published as WO96/14612 May 17, 1996.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention relates to a monitoring system for an industrial or technical plant, in particular for a power station plant, having a number of plant parts which can be displayed as information elements on a display unit.

In a control room for controlling an industrial plant, in particular a power station plant, large quantities of various measurement data occur continuously and in their entirety describe a plant state or operating state. The operating personnel of the plant have the task of identifying the measurement data or measurement variables that are respectively relevant to the operating state as well as the task of following, analyzing and interpreting their values in relation to the state of the plant. At the same time, the guidance of the process from the control room is largely determined through screens by way of standards and guidelines in the form of regulations. Those regulations include symbols for parts of the plant or elements of the plant such as, for example, pumps and valves, the coloring of indicators and the construction of the indicators of a control system. In addition to the various indicators, there is commonly a plant diagram which represents the entire plant in overview. However, with increasing automation and complexity of such an industrial plant, the number of measurement data that are recorded also increases, and therefore the probability that information important to the respective operating state of the plant is not identified as such in good time. Corresponding counter measures can thus only be belatedly initiated.

SUMMARY OF THE INVENTION

It is accordingly an object of the invention to provide a monitoring system for an industrial or technical plant, in particular for a power station plant, which overcomes the hereinafore-mentioned disadvantages of the heretofore-known devices of this general type, with which special features in a plant process are indicated directly and with which it is possible to take counter measures in good time, in particular in the case of disturbances.

With the foregoing and other objects in view there is provided, in accordance with the invention, a monitoring system for an industrial, in particular for a power station plant, having a number of plant parts, comprising a display unit for displaying the plant parts as information elements positioned by using process data relevant for a plant state, each two information elements being spaced apart by a distance representing a degree of their contextual similarity.

In this configuration, the invention proceeds from the consideration that, on the basis of the mathematical model of formal concept analysis, large quantities of process data can be filtered, compressed and/or structured in accordance with the principle that "contextual proximity corresponds to spatial proximity" in relation to their significance for the plant state. The fundamentals of formal concept analysis are, for example, summarized in publications M. Luxemburger entitled: "Implikationen, Abhangigkeiten und Galois-Abbildungen. Beitrage zur formalen Begriffsanalyse" Implications, Dependencies and Galois Mapping. Contributions to Formal Concept Analysis!, Dissertation, TH Darmstadt (1993) and Proc. NATO Adv. Study Inst., Banff, Canada 1981, pages 445-470 (1982), as well as a publication by G. Kalmbach entitled: "Diskrete Mathematik. Ein Intensivkurs fur Studienanfanger mit Turbo-Pascal-Programmen" Discrete Mathematics. An Intensive Course for Beginners, with Turbo-Pascal Programs! (1981).

A list of features is provided from the information system of the industrial plant, which is part of the operating system of the plant. The features as a whole describe all of the possible operating states or plant states. The features themselves are, for example, status messages or other messages which describe the state of a part of the plant uniquely and which, for their part, can be members of series of messages. The assignment of the features to the parts of the plant is carried out by using parameters that are currently recorded or modeled (simulated) and which are likewise provided by the information system of the industrial plant.

The contextual similarity or the proximity in terms of content of two parts of the plant is then determined in each case by the relationship of the number of the features common to them to the number of those features exhibited by at least one of the parts of the plant. In other words: in each case two parts of the plant which agree in all features are classified as particularly close in terms of content, whereas two parts of the plant which agree in none of the features are classified as not close in terms of content.

The proximity in terms of content of two parts of the plant is transformed for the graphical representation into a spatial proximity of information elements representing the parts of the plant. The spatial proximity of two features is expediently determined in each case in a manner corresponding to the degree of their contextual equivalence, with use being made of the number of those parts of the plant which exhibit these features in common. The assignment of features to each part of the plant exhibiting them, using the parameters, uniquely determines the correlation or the relationship between these features and this part of the plant.

In accordance with another feature of the invention, the display unit displays a multiplicity of features completely characterizing the industrial plant and the parts of the plant in terms of their content as information elements positioned with a distance between each two information elements representing a degree of their contextual equivalence.

In accordance with a further feature of the invention, the display unit displays the information elements positioned in relation to one another with a distance between an information element representing a feature and an information element representing a part of the plant in each case being consistent with a degree of association of the feature with the part of the plant.

The parameters provided by the information system of the industrial plant are expediently a component part of event messages which characterize changes of operating states or deviations from a normal state of the plant. In this case, the event messages are uniquely assigned to the corresponding parts of the plant using specific identifiers.

The graphical representation which is generated can be merely a configuration of information elements representing parts of the plant or merely a configuration of information elements representing features. Preferably, however, information elements both of parts of the plant and of features are represented graphically. In this case, the positioning of the information elements in relation to one another within the configuration is determined in such a manner that the following criterion is fulfilled: if a part of the plant exhibits a feature, the distance of its information elements in relation to one another is smaller than a prescribable first limiting value. If a part of the plant does not exhibit a feature, the distance between its information elements is greater than a prescribable second limiting value. Therefore, the distance between these information elements is consistent with the degree of association of this feature with this part of the plant.

In order to enable information to be provided to the operating personnel which is important for an identification of the respective plant state in a particularly simple and/or clear manner, the measurement data picked up within the plant process or parameters derived therefrom are filtered.

For this purpose, in accordance with an added feature of the invention, there is provided a filter module with which it is determined which of the parts of the plant are represented, on the basis of a prescribable criterion. For example, those parts of the plant can be represented which agree in one feature such as, for example, in the state "disturbance"/"no disturbance", or in the status ON/OFF.

In an advantageous way, a time window is prescribed as a criterion, so that relationships or interactions can be detected between those parts of the plant which report disturbances within a specific time interval. As a result, conclusions can be drawn with respect to causative disturbances, in contrast to symptomatic disturbances.

In order to be able to detect a development trend in the direction of a disturbance in good time, a time window can advantageously also be prescribed as a feature. In this way, it is possible to provide a time-based ordering of the information elements representing the parts of the plant and features. Information elements of successive event messages are preferably represented together as a state complex. The state complex in this case can have a characteristic structure, the pattern of which has a direct relationship with a system behavior.

In accordance with a concomitant feature of the invention, there is provided a data memory for storing a system state that is forecast from the common representation of the information elements. In this way, it is possible to already counteract an incipient disturbance in a suitable manner during the initial stage.

This state complex can be used as a reference complex and compared with a current state complex. Patterns which are characteristic of a specific plant behavior are then prescribed in this reference complex. For example, a disturbance proceeding from a rapid closure of a safety valve in a power station plant can be provided in the form of a reference complex. An on-line incipient rapid closure can therefore be detected on the basis of the disturbance messages proceeding therefrom.

The information space in which the information elements are represented is n-dimensional and preferably 3-dimensional. Three spatial coordinates are therefore preferably determined in order to fix the position of each information element in this information space. A 3-dimensional representation is thus possible on a suitable display device, for example on a monitor screen, in the control room.

Other features which are considered as characteristic for the invention are set forth in the appended claims.

Although the invention is illustrated and described herein as embodied in a monitoring system for an industrial plant, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims.

The construction and method of operation of the invention, however, together with additional objects and advantages thereof will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a functional diagram of a monitoring system for an industrial plant;

FIG. 2 is a diagram showing a configuration of information elements representing parts of the plant and their features, which configuration is characteristic of an operating state of the industrial plant; and

FIG. 3 is a diagram showing a state complex characteristic of a trend of an operating behavior of the plant.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring now to the figures of the drawings in detail and first, particularly, to FIG. 1 thereof, there is seen an exemplary embodiment of a process sequence within a plant component 1 which is part of an entire process of a power station plant that is not shown in greater detail. The plant component 1 includes a pump a₁, connected in a steam line 2, a steam valve a₂ connected upstream of the pump a₁ and a blow-off control valve a₃ in a branch line 8. A flow sensor 12 provided between the pump a₁ and the steam valve a₂ registers the quantity of steam flowing through the steam line 2 per unit time. In addition, a pressure sensor 13 is provided on the pressure side of the pump a₁. The pump a₁ is provided with a rotational speed sensor 14. The steam valve a₂ and the blow-off control valve a₃ have respective control and feedback elements 15 and 16. The pump a₁ and the steam valve a₂, as well as the blow-off control valve a₃ are also designated below as parts a₁ to a₃ or merely as parts a_(i) of the plant.

Measured values registered by the sensors 12, 13 and 14, as well as feedback signals output by the feedback elements 15 and 16, are fed in the form of process data PD_(i) to an automation system 18a and a process control information system 18b.

The process data PD_(i) are pre-processed in automation units of the automation and information system 18a, 18b of the power station plant. If necessary, control signals S_(i) are output to the plant parts a_(i) of the plant component 1. Converging information about measurement, regulation and control events and about the signal generation is stored in the information system 18b. The power station plant with its plant parts a_(i), such as, for example, the pump a₁ and the valves a₂ and a₃ of the plant component 1, are automatically controlled through the use of processes running within the automation and information system 18a, 18b.

Parameters P_(i) that are relevant to the plant process and thus also to the process running within the plant component 1 are generated by the automation and information system 18a, 18b and combined into messages M_(i), by using the process data PD_(i) and the control signals S_(i). These messages M_(i) also include identifiers identifying the parts a_(i) of the plant.

The parameters P_(i) and/or the messages M_(i) are fed to an analysis module 20 of the monitoring system through a filter module 21. Features m_(i) characterizing the plant process are furthermore provided to the analysis module 20.

The features m_(i) are status messages, disturbance messages and state messages as well as functional, process-technological and structural details of the parts a_(i) of the plant or plant components. These details describe the mode of operation of the parts of the plant and their configuration and assignment within the entire plant. Within the analysis module 20, the presence of the features m_(i) is checked for each part a_(i) of the plant by using the parameters P_(i), or on the basis of the messages M_(i) for a prescribed time window. For this purpose, a context KT_(i) is generated for each time window. A unique assignment of features m_(i) to parts a_(i) of the plant is carried out in the context, in the form of a matrix 22.

Spatial coordinates are assigned to the parts a_(i) of the plant and/or the features m_(i) in a positioning module 24 of the monitoring system by using information present in the contexts Kt_(i). At the same time, in accordance with the principle that "contextual proximity corresponds to spatial proximity" the degree of the correlations between combinations of parts a_(i) of the plant and between combinations of features m_(i) is determined. This is done in such a way that, for example, for two parts a_(i) of the plant, the ratio of the number of features m_(i) common to them to the number of the features m_(i) which is exhibited by at least one of the two parts a_(i) of the plant, is determined. A quantitative measure for the degree of correlation between these two parts a_(i) of the plant then results from this ratio. If, for example, both parts a_(i) of the plant exhibit only common features m_(i), the two parts a_(i) of the plant are correlated to a high degree. In contrast, two parts a_(i) of the plant are not correlated with each other if they differ in all of the features m_(i). This quantitative measure of the correlation between two parts a_(i) of the plant is transformed into a corresponding distance of their spatial coordinates from each other. The correlation of the features m_(i) with one another is determined in an analogous manner, by making analogous use of the number of the parts a_(i) of the plant exhibiting them.

A graphic representation for the parts a_(i) of the plant and the features m_(i) is generated in a graphic module 26 of the monitoring system on the basis of this spatial assignment. Firstly, information elements I_(i) (a_(i)) (shown in FIG. 3) for the parts a_(i) of the plant and information elements I_(i) (m_(i)) (shown in FIG. 3) for the features m_(i) are generated by the graphic module 26 and positioned on a display 28 on the basis of the spatial coordinates. The common configuration of the information elements I_(i) (a_(i)) and I_(i) (m_(i)) is carried out in this case under the following condition: the distance between an information element I_(i) (m_(i)) and an information element I_(i) (a_(i)) does not exceed a prescribed first limiting value if this part a_(i) of the plant exhibits this feature m_(i), and this distance does not fall below a prescribed second limiting value if this part a_(i) of the plant does not exhibit this feature m_(i). In other words: if a part a_(i) of the plant exhibits a feature m_(i), the information elements I_(i) (a_(i)) and I_(i) (m_(i)) representing them may not be positioned too far from each other. If, in contrast, a part a_(i) of the plant does not exhibit a feature m_(i), the information elements I_(i) (a_(i)) and I_(i) (m_(i)) representing them may not be too close.

If, for example, a disturbance in a part of the non-illustrated plant connected in the steam line 2 leads to a pressure increase in the steam line 2, the rotational speed of the pump a₁ falls, and the blow-off control valve a₃ opens. The automation system 18a thereupon closes the steam valve a₂, so that the rotational speed of the pump a₁ normalizes and the blow-off control valve a₃ closes once more. After a subsequent renewed opening of the steam valve a₂ by the automation system 18a, the pressure within the steam line 2 increases once more, so that the process repeats until the disturbance has been eliminated.

Process data PD_(i) describing this process, that is to say the steam quantity registered by the flow sensor 12 and the steam pressure registered by the pressure sensor 13, as well as the pump rotational speed registered by the rotational speed sensor 14, are fed to the process-control information system 18b. Control signals S_(i) for opening or closing the valves a₂ and a₃ are output by the automation system 18a to the plant component 1 as a reaction to the process data PD_(i) entering into the process-control information system 18b.

Messages M_(i) are drawn up from the process data PD_(i) and the control signals S_(i) for the purposes of analysis. Such messages M_(i) are, for example: "time t_(i) --plant component 1--pressure sensor 13--pressure too high--disturbance--high priority"; "time t₂ --plant component 1--rotational speed sensor 14--rotational speed too low--disturbance--high priority"; "time t₃ --plant component 1--blow-off valve a₃ --status signal open"; "time t₃ --plant component 1--steam valve a₂ --status signal closed"; and so on.

Through the use of these messages M_(i), features m_(i) are assigned in the analysis module 20 to the parts a₁, a₂ and a₃ of the plant. In other words, through the use of the messages M_(i), the presence of each feature m_(i) of these parts a₁, a₂ and a₃ of the plant is checked. All of the features m_(i) belonging to the message component "plant component 1" are thus assigned to each of the parts a₁, a₂ and a₃ of the plant. As a result, the parts a₁, a₂ and a₃ of the plant already agree in a multiplicity of features m_(i), so that they are correlated to a high degree. Accordingly, these parts a₁ to a₃ of the plant have closely adjacent spatial coordinates assigned to them in the positioning module 24. A graphic representation, which is drawn up on the basis of this spatial assignment in the graphic module 26, is shown in FIG. 2.

As can be seen from FIG. 2, in this case the information elements I₁ (a₁) to I₃ (a₃) and I₁ (m_(i)) to I₃ (m_(i)) which are assigned to the parts a₁ to a₃ of the plant and the features m_(i), are shown together. In order to provide improved clarity, the information elements I₁₋₃ (m_(i)) of the features m_(i) and the information elements I_(i) (a_(i)) of the parts a₁ to a₃ of the plant exhibiting these features m_(i) are connected by so-called incidence lines L. The information elements I₁₋₃ (a₁₋₃) are represented in the form of squares or cubes, while the information elements I₁₋₃ (m_(i)) of the features m_(i) are illustrated in the form of circles or spheres. The influence of the parts a₁, a₂ and a₃ of the plant on one another in this case is symbolized by action arrows W.

The messages or event messages M_(i) also exhibit time features. A time correlation of the parts a_(i) of the plant can be derived on the basis of these time features. For example, two of the above-mentioned messages M_(i) exhibit the same time feature "T₃ ", so that simultaneity of the associated events is drawn as the conclusion.

Information elements I_(i) (a_(i), m_(i)) which are correlated in time or in another way are represented in the form of a state complex for the purpose of a diagnosis. This is shown in FIG. 3. A state complex of this type has a characteristic pattern according to the type of a disturbance, on the basis of which the type and development of the disturbance over time can be identified. Such a state complex can also be stored as a reference complex which can be used for a comparison with current events. 

We claim:
 1. A monitoring system for an industrial plant having a number of plant parts, comprising:a display unit for displaying a number of parts of an industrial plant as information elements positioned by using process data relevant for a plant state, each two information elements spaced apart by a distance representing a degree of their contextual similarity.
 2. The monitoring system according to claim 1, wherein said display unit displays a multiplicity of features completely characterizing the industrial plant and the parts of the plant in terms of their content as information elements positioned with a distance between each two information elements representing a degree of their contextual equivalence.
 3. The monitoring system according to claim 2, wherein said display unit displays the information elements positioned in relation to one another with a distance between an information element representing a feature and an information element representing a part of the plant in each case being consistent with a degree of association of the feature with the part of the plant.
 4. The monitoring system according to claim 1, including a filter module for selecting process data, parameters, parts of the plant or features using a prescribable criterion.
 5. The monitoring system according to claim 1, including a data memory for plant-state-characterizing configurations of the information elements in state complexes. 